141 lines
7.4 KiB
Markdown
141 lines
7.4 KiB
Markdown
---
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title: 45-canonical-transformations
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---
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Canonical transformations
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143
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Expanding the derivative on the left-hand side and putting the force F = - auld gives
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d2r/dl2=[F-(F.t)t]/2(E-U),
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where t = dr/dl is a unit vector tangential to the path. The difference F-(F. t)t is the com-
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ponent Fn of the force normal to the path. The derivative d2r/dl2 = dt/dl is known from
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differential geometry to be n/R, where R is the radius of curvature of the path and n the unit
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vector along the principal normal. Replacing E-U by 1mv2, we have (mv2/R)n = Fn, in
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agreement with the familar expression for the normal acceleration in motion in a curved
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path.
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$45. Canonical transformations
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The choice of the generalised co-ordinates q is subject to no restriction;
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they may be any S quantities which uniquely define the position of the system
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in space. The formal appearance of Lagrange's equations (2.6) does not
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depend on this choice, and in that sense the equations may be said to be
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invariant with respect to a transformation from the co-ordinates q1, q2,
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to any other independent quantities Q1, Q2, The new co-ordinates Q are
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functions of q, and we shall assume that they may explicitly depend on the
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time, i.e. that the transformation is of the form
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Qi=Qi(q,t)
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(45.1)
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(sometimes called a point transformation).
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Since Lagrange's equations are unchanged by the transformation (45.1),
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Hamilton's equations (40.4) are also unchanged. The latter equations, how-
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ever, in fact allow a much wider range of transformations. This is, of course,
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because in the Hamiltonian treatment the momenta P are variables inde-
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pendent of and on an equal footing with the co-ordinates q. Hence the trans-
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formation may be extended to include all the 2s independent variables P
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and q:
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Qt=Qi(p,q,t),
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Pi = Pi(p, q,t).
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(45.2)
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This enlargement of the class of possible transformations is one of the im-
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portant advantages of the Hamiltonian treatment.
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The equations of motion do not, however, retain their canonical form
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under all transformations of the form (45.2). Let us derive the conditions
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which must be satisfied if the equations of motion in the new variables P, Q
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are to be of the form
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(45.3)
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with some Hamiltonian H'(P,Q). When this happens the transformation is
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said to be canonical.
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The formulae for canonical transformations can be obtained as follows. It
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has been shown at the end of §43 that Hamilton's equations can be derived
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from the principle of least action in the form
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(45.4)
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144
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The Canonical Equations
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§45
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in which the variation is applied to all the co-ordinates and momenta inde-
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pendently. If the new variables P and Q also satisfy Hamilton's equations,
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the principle of least action
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0
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(45.5)
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must hold. The two forms (45.4) and (45.5) are equivalent only if their inte-
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grands are the same apart from the total differential of some function F of
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co-ordinates, momenta and time.t The difference between the two integrals
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is then a constant, namely the difference of the values of F at the limits of
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integration, which does not affect the variation. Thus we must have
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=
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Each canonical transformation is characterised by a particular function F,
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called the generating function of the transformation.
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Writing this relation as
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(45.6)
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we see that
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Pi = 0F/dqi, =-0F/JQi H' = H+0F/dt;
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(45.7)
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here it is assumed that the generating function is given as a function of the
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old and new co-ordinates and the time: F = F(q, Q, t). When F is known,
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formulae (45.7) give the relation between p, q and P, Q as well as the new
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Hamiltonian.
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It may be convenient to express the generating function not in terms of the
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variables q and Q but in terms of the old co-ordinates q and the new momenta
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P. To derive the formulae for canonical transformations in this case, we must
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effect the appropriate Legendre's transformation in (45.6), rewriting it as
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=
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The argument of the differential on the left-hand side, expressed in terms of
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the variables q and P, is a new generating function (q, P, t), say. Thent
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= Qi = ID/OPi, H' = H+d
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(45.8)
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We can similarly obtain the formulae for canonical transformations in-
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volving generating functions which depend on the variables P and Q, or
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p and P.
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t We do not consider such trivial transformations as Pi = api, Qi = qt,H' = aH, with a an
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arbitrary constant, whereby the integrands in (45.4) and (45.5) differ only by a constant
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factor.
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+ If the generating function is = fi(q, t)Pi, where the ft are arbitrary functions, we
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obtain a transformation in which the new co-ordinates are Q = fi(q, t), i.e. are expressed
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in terms of the old co-ordinates only (and not the momenta). This is a point transformation,
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and is of course a particular canonical transformation.
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§45
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Canonical transformations
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145
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The relation between the two Hamiltonians is always of the same form:
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the difference H' - H is the partial derivative of the generating function with
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respect to time. In particular, if the generating function is independent of
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time, then H' = H, i.e. the new Hamiltonian is obtained by simply substitut-
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ing for P, q in H their values in terms of the new variables P, Q.
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The wide range of the canonical transformations in the Hamiltonian treat-
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ment deprives the generalised co-ordinates and momenta of a considerable
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part of their original meaning. Since the transformations (45.2) relate each
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of the quantities P, Q to both the co-ordinates q and the momenta P, the
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variables Q are no longer purely spatial co-ordinates, and the distinction
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between Q and P becomes essentially one of nomenclature. This is very
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clearly seen, for example, from the transformation Q = Pi, Pi = -qi,
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which obviously does not affect the canonical form of the equations and
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amounts simply to calling the co-ordinates momenta and vice versa.
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On account of this arbitrariness of nomenclature, the variables P and q in
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the Hamiltonian treatment are often called simply canonically conjugate
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quantities. The conditions relating such quantities can be expressed in terms
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of Poisson brackets. To do this, we shall first prove a general theorem on the
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invariance of Poisson brackets with respect to canonical transformations.
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Let [f,g]p,a be the Poisson bracket, for two quantities f and g, in which
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the differentiation is with respect to the variables P and q, and [f,g]p,Q that
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in which the differentiation is with respect to P and Q. Then
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(45.9)
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The truth of this statement can be seen by direct calculation, using the for-
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mulae of the canonical transformation. It can also be demonstrated by the
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following argument.
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First of all, it may be noticed that the time appears as a parameter in the
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canonical transformations (45.7) and (45.8). It is therefore sufficient to prove
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(45.9) for quantities which do not depend explicitly on time. Let us now
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formally regard g as the Hamiltonian of some fictitious system. Then, by
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formula (42.1), [f,g]p,a = df/dt. The derivative df/dt can depend only on
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the properties of the motion of the fictitious system, and not on the particular
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choice of variables. Hence the Poisson bracket [f,g] is unaltered by the
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passage from one set of canonical variables to another.
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Formulae (42.13) and (45.9) give
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[Qi, Qk]p,a = 0, [Pi,Pk]p,a = 0,
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(45.10)
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These are the conditions, written in terms of Poisson brackets, which must
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be satisfied by the new variables if the transformation P, q P, Q is canonical.
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It is of interest to observe that the change in the quantities P, q during the
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motion may itself be regarded as a series of canonical transformations. The
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meaning of this statement is as follows. Let qt, Pt be the values of the canonical
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t Whose generating function is
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6*
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146
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The Canonical Equations
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